Haptic fMRI: Using classification to quantify task-correlated noise during goal-directed reaching motions

Neuroimaging artifacts in haptic functional magnetic resonance imaging (Haptic fMRI) experiments have the potential to induce spurious fMRI activation where there is none, or to make neural activation measurements appear correlated across brain regions when they are actually not. Here, we demonstrate that performing three-dimensional goal-directed reaching motions while operating Haptic fMRI Interface (HFI) does not create confounding motion artifacts. To test for artifacts, we simultaneously scanned a subject's brain with a customized soft phantom placed a few centimeters away from the subject's left motor cortex. The phantom captured task-related motion and haptic noise, but did not contain associated neural activation measurements. We quantified the task-related information present in fMRI measurements taken from the brain and the phantom by using a linear max-margin classifier to predict whether raw time series data could differentiate between motion planning or reaching. fMRI measurements in the phantom were uninformative (2σ, 45-73%; chance=50%), while those in primary motor, visual, and somatosensory cortex accurately classified task-conditions (2σ, 90-96%). We also localized artifacts due to the haptic interface alone by scanning a stand-alone fBIRN phantom, while an operator performed haptic tasks outside the scanner's bore with the interface at the same location. The stand-alone phantom had lower temporal noise and had similar mean classification but a tighter distribution (bootstrap Gaussian fit) than the brain phantom. Our results suggest that any fMRI measurement artifacts for Haptic fMRI reaching experiments are dominated by actual neural responses.

[1]  Oussama Khatib,et al.  Mapping stiffness perception in the brain with an fMRI-compatible particle-jamming haptic interface , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[2]  Dejan B. Popovic,et al.  Influence of planar manipulandum to the hand trajectory during point to point movement , 2011, 2011 IEEE International Conference on Rehabilitation Robotics.

[3]  Etienne Burdet,et al.  A 2-DOF fMRI compatible haptic interface to investigate the neural control of arm movements , 2006, Proceedings 2006 IEEE International Conference on Robotics and Automation, 2006. ICRA 2006..

[4]  Jörn Diedrichsen,et al.  Detecting and adjusting for artifacts in fMRI time series data , 2005, NeuroImage.

[5]  J. Platt Sequential Minimal Optimization : A Fast Algorithm for Training Support Vector Machines , 1998 .

[6]  Jens Sommer,et al.  MRI Phantoms – Are There Alternatives to Agar? , 2013, PloS one.

[7]  Etienne Burdet,et al.  An MR compatible robot technology , 2003, 2003 IEEE International Conference on Robotics and Automation (Cat. No.03CH37422).

[8]  Jonathan Winawer,et al.  GLMdenoise: a fast, automated technique for denoising task-based fMRI data , 2013, Front. Neurosci..

[9]  Robert Riener,et al.  fMRI assessment of upper extremity related brain activation with an MRI-compatible manipulandum , 2011, International Journal of Computer Assisted Radiology and Surgery.

[10]  Oussama Khatib,et al.  Haptic fMRI: Combining functional neuroimaging with haptics for studying the brain's motor control representation , 2013, 2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[11]  Oussama Khatib,et al.  Haptic fMRI: Accurately estimating neural responses in motor, pre-motor, and somatosensory cortex during complex motor tasks , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[12]  Hiroshi Imamizu,et al.  Human cerebellar activity reflecting an acquired internal model of a new tool , 2000, Nature.

[13]  Nikos K Logothetis,et al.  Interpreting the BOLD signal. , 2004, Annual review of physiology.

[14]  N. Logothetis What we can do and what we cannot do with fMRI , 2008, Nature.

[15]  Marko Munih,et al.  Phantom haptic device upgrade for use in fMRI , 2009, Medical & Biological Engineering & Computing.

[16]  Etienne Burdet,et al.  fMRI Compatible Haptic Interfaces to Investigate Human Motor Control , 2006, ISER.

[17]  Yasmin L. Hashambhoy,et al.  Neural Correlates of Reach Errors , 2005, The Journal of Neuroscience.

[18]  Kiyoyuki Chinzei,et al.  MRI-Compatible Robotics , 2008, IEEE Engineering in Medicine and Biology Magazine.

[19]  M. Kenward,et al.  An Introduction to the Bootstrap , 2007 .